The present invention relates to a method and kit for amplifying and detecting a quantity of nucleic acid. The invention is particularly relevant to isothermal amplification techniques carried out on a flow based assay device. The amplified nucleic acid may be detected on the device using an optical read-out.

The present invention relates to a method and kit for amplifying and detecting a quantity of nucleic acid. The invention is particularly relevant to isothermal amplification techniques carried out on a flow based assay device. The amplified nucleic acid may be detected on the device using an optical read-out.

Provided herein are methods of detecting target analytes, such as nucleic acids, for example microRNAs using an enhanced Tyramide Signal Amplification (TSA) method that employs probes tagged with tyramide-binding groups to amplify the effects of the TSA. The accessibility of the tyramide-binding groups, such as hydroxyphenyl groups, provides for large improvements in signal due to faster reaction with the radicals. The present invention further includes the application of the assay for detecting specific microRNAs.

Provided herein are methods of detecting target analytes, such as nucleic acids, for example microRNAs using an enhanced Tyramide Signal Amplification (TSA) method that employs probes tagged with tyramide-binding groups to amplify the effects of the TSA. The accessibility of the tyramide-binding groups, such as hydroxyphenyl groups, provides for large improvements in signal due to faster reaction with the radicals. The present invention further includes the application of the assay for detecting specific microRNAs.

Method of identifying a cognate nucleotide (i.e., the “next correct nucleotide”) for a primed template nucleic acid molecule. In some embodiments, an ordered or random array of primed target nucleic acids characterized by different cognate nucleotides can be evaluated using a single imaging step to identify different cognate nucleotides for a collection of different primed template nucleic acid molecules. An optional incorporation step can follow the identifying step. A polymerase different from the ones used in the binding and examination steps can be used to incorporate a nucleotide, such as a reversible terminator nucleotide, preliminary to identification of the next cognate nucleotide.

Method of identifying a cognate nucleotide (i.e., the “next correct nucleotide”) for a primed template nucleic acid molecule. In some embodiments, an ordered or random array of primed target nucleic acids characterized by different cognate nucleotides can be evaluated using a single imaging step to identify different cognate nucleotides for a collection of different primed template nucleic acid molecules. An optional incorporation step can follow the identifying step. A polymerase different from the ones used in the binding and examination steps can be used to incorporate a nucleotide, such as a reversible terminator nucleotide, preliminary to identification of the next cognate nucleotide.

This disclosure related to methods of detecting mechanical forces required to separate ligand and receptor interactions. In certain embodiments, this disclosure relates to methods of detecting mechanical forces between a ligand and receptor, where the ligand is immobilized on a surface using weaker forces. Ligand-receptor forces lead to dissociation of the ligand that can be detected and amplified. In certain embodiments, the disclosure relates to methods of detecting ligand and receptor interactions comprising linking a ligand to one of two binding partners, wherein the binding partners have attracting forces that are less than the forces between the ligand and a receptor of the ligand such that when the ligand binds the receptor, the binding partners will separate. Separation of the binding partners can be detected.

This disclosure related to methods of detecting mechanical forces required to separate ligand and receptor interactions. In certain embodiments, this disclosure relates to methods of detecting mechanical forces between a ligand and receptor, where the ligand is immobilized on a surface using weaker forces. Ligand-receptor forces lead to dissociation of the ligand that can be detected and amplified. In certain embodiments, the disclosure relates to methods of detecting ligand and receptor interactions comprising linking a ligand to one of two binding partners, wherein the binding partners have attracting forces that are less than the forces between the ligand and a receptor of the ligand such that when the ligand binds the receptor, the binding partners will separate. Separation of the binding partners can be detected.

The present invention relates to a method for detecting a target RNA polynucleotide by using a catcher polynucleotide which anneals to at least a portion of the target RNA polynucleotide, and a catalytically-inactive crRNA-guided (CRISPR RNA) RNA-binding protein which binds to the target RNA polynucleotide. Further envisaged is a kit for detecting a specific target RNA polynucleotide comprising inter alia one or more catcher polynucleotides complementary to at least a portion of the target RNA polynucleotide, a mature crRNA molecule which is specific for a target sequence on the target RNA polynucleotide and a catalytically-inactive crRNA-guided RNA-binding protein; as well as the use of these ingredients for the detection of the target RNA polynucleotide.

The present invention relates to a method for detecting a target RNA polynucleotide by using a catcher polynucleotide which anneals to at least a portion of the target RNA polynucleotide, and a catalytically-inactive crRNA-guided (CRISPR RNA) RNA-binding protein which binds to the target RNA polynucleotide. Further envisaged is a kit for detecting a specific target RNA polynucleotide comprising inter alia one or more catcher polynucleotides complementary to at least a portion of the target RNA polynucleotide, a mature crRNA molecule which is specific for a target sequence on the target RNA polynucleotide and a catalytically-inactive crRNA-guided RNA-binding protein; as well as the use of these ingredients for the detection of the target RNA polynucleotide.